The Effect of Food Polymers (Pectin, Alginate, and Gum Arabic) on Carbonated Drink-Induced Enamel Demineralization: An In Vitro Study

Jinu George; Jolly Mary Varughese; Subija Kunnumpurath Narayanankutty; Divia Attuvalappil Rajan; Dhanya Shaji; Christalin Ramakrishnan

doi:10.7759/cureus.56385

The Effect of Food Polymers (Pectin, Alginate, and Gum Arabic) on Carbonated Drink-Induced Enamel Demineralization: An In Vitro Study

Cureus. 2024 Mar 18;16(3):e56385. doi: 10.7759/cureus.56385. eCollection 2024 Mar.

Authors

Jinu George¹, Jolly Mary Varughese², Subija Kunnumpurath Narayanankutty¹, Divia Attuvalappil Rajan¹, Dhanya Shaji¹, Christalin Ramakrishnan¹

Affiliations

¹ Department of Conservative Dentistry and Endodontics, Government Dental College, Thrissur, IND.
² Department of Conservative Dentistry and Endodontics, Government Dental College, Trivandrum, IND.

Abstract

Introduction: The increased use of soft drinks leads to a high prevalence of dental erosion (DE), and the use of polymers can decrease tooth demineralization by a carbonated drink. Assessment of the effect of food-approved polymers such as highly esterified pectin (HP), propylene glycol alginate (PGA), and gum arabic (GA) on their efficiency to reduce enamel demineralization on addition with a commercially available carbonated drink was the main objective of this study.

Materials and methods: For this study, 300 premolar teeth were studied for enamel erosion and were divided into five groups consisting of 60 samples in each group. The teeth treated with distilled water had negative control, a commercially available carbonated drink with pH 2.7 had positive control, and food polymers were added individually to the carbonated drink in a specified quantity with minimal pH change and were taken as groups A, B, and C, respectively. The enamel erosion that occurred in study groups was measured using a laser fluorescence spectroscopic system with laser excitation at 404 nm at different treatment times (30, 60, and 120 seconds). Results: Demineralization was less in samples treated with polymer added to carbonated drink solutions compared to samples exposed to plain carbonated drink. As the time of exposure increased up to 120 seconds, a significant decrease in demineralization occurred in polymer-treated groups of samples as against plain carbonated drink with HP showing more decreased demineralization with extended exposure periods compared to other polymers. The surface morphology of tooth samples exhibited the anti-erosive effect of polymers, and the scanning electron microscopic pictures revealed a smoother surface for the polymer-added group.

Conclusion: This study shows the efficacy of HP, PGA, and GA on reducing the effect of carbonated drink-induced enamel demineralization, and these polymers' addition to drinks can be an innovative way to reduce the demineralization potential of carbonated acidic drinks.

Keywords: carbonated drinks; enamel demineralization; food-approved polymers; laser-induced fluorescence; scanning electron microscopy.